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Arterial Spin Labeling at 7T - Double Edged Sword. Jiong-Jiong Wang, PhD University of Pennsylvania, Philadelphia, PA. Spin Labeling Strategies. ● Continuous ASL (CASL) vs. Pulsed ASL (PASL) Greater SNR, higher MT effect & SAR, technically challenging ● Pseudo-CASL (pCASL)
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Arterial Spin Labeling at 7T- Double Edged Sword Jiong-Jiong Wang, PhD University of Pennsylvania, Philadelphia, PA
Spin Labeling Strategies ●Continuous ASL (CASL) vs. Pulsed ASL (PASL) Greater SNR, higher MT effect & SAR, technically challenging ● Pseudo-CASL (pCASL) Combines advantages of PASL and CASL ● Blood water is used as a natural tracer, with a half-life of blood T1
Advantages of High Field ASL T1 follows cube root increase with field strength (ω0.3), e.g. blood T1 = 1.2s at 1.5T, 1.5s at 3T, 2s at 7T Substantial ASL signal gain due to SNR and prolonged T1 at high field (ω1.3). Wang et al MRM 2002
T2/T2* Effect at High Field Estimated perfusion signal gain at high field strength with TE=20ms. Experimental validation, approximately 2 times SNR at 4T vs. 1.5T. CASL is 1.5 SNR vs. PASL. Wang et al MRM 2002
TE Dependence of ASL St Lawrence & Wang MRM 2005
Sample ASL Image at 7T CASL with separate neck labeling coil by NINDS group Talagala et al ISMRM Perfusion workshop 2007
Pseudo-continuous ASL • 50% SNR gain compared to PASL • 30% efficiency gain compared to CASL • Expect impressive image quality at 7T Garcia, de Bazelaire & Alsop, ISMRM 2005 Wu et al. MRM 2007
Single-shot 3D Perfusion Imaging with GRASE SPM (p<0.001, n=5) results demonstrating significantly increased perfusion sensitivity in orbitofrontal cortex with GRASE as compared to EPI. Fernandez-Seara et al. MRM (2005)
Trade High SNR for High Spatial Resolution at 7T Increased ASL and BOLD signal change with higher spatial resolution Pfeufferet al. MRM (2002)
High Resolution Perfusion Imaging with pCASL, Background Suppression & Array Coil Wang et al (2007)
BOLD signal is proportional to the static magnetic field strength (B0) for large vessels (diameter > 8 μm, venules and veins) and to B02 for small vessels (diameter < 8 μm, capillaries) (Ogawa et al 1993) Change of transverse relaxation rate ∆R*2 in the capillary bed by a power of the field strength varying from 1 to 2 (Turner et al., 1993) Validation studies by Yang et al 1999, Fera et al 2004, Okada et al 2005. BOLD fMRI Okada et al Acad Radio 2005
ASL Perfusion fMRI Wang et al MRM 2002
Two-Compartment Perfusion Model Blood in capillary and vein is affected by T2/T2* effects. Solution: shorter TE and post-labeling delay St Lawrence & Wang MRM 2005
Physiological Noise at High Field Kruger & Glover MRM 2001 Triantafyllou et al NeuroImage 2005
Physiological Noise in ASL Wu et al (in preparation)
3D GRASE ASL with Background Suppression NO SUPPRESSION • 10X suppression of temporal fluctuation • Benefit at high field 0.7% WITH SUPPRESSION 8.4% Fernandez-Seara et al. MRM 2008
Power Deposition at High Field (SAR) SAR increases 4 fold at 7T vs. 3TPASL is ok, for CASL/pCASL parameter optimization, separate labeling coil? Wang et al. Radiology 2005
Power Deposition at High Field (SAR) B1 G (or RF Gap) can be reduced without affecting efficiency for CASL and pCASL Maccotta et al. NMR Biomed 1997
New Capabilities – Parallel Transmit Localized labeling ?
Estimation of Venous T2* and Oxygenation For grey and white matter respectively, CBF = 70.2 ± 9.3 and 41.1 ± 7.6 ml/100g/min, and venous T2* = 10.8 ± 4.2 and 9.3 ± 4.7 ms. Sensitivity may improve at 7 T St Lawrence & Wang ISMRM 2005
Estimation of Water Permeability using DW ASL Wang et al JCBFM 2007
Summary Potential large SNR gain at 7T – high spatial resolution Creative ways to deal with SAR, T2* effects, implementing PASL, CASL & pCASL Effective approaches to reduce physiological noise Potentials to measure blood oxygenation, permeability Utilizing parallel excitation for localized labeling